ECTS - Industrial Automation and Robotics Technology

Industrial Automation and Robotics Technology (MECE574) Course Detail

Course Name	Course Code	Season	Lecture Hours	Application Hours	Lab Hours	Credit	ECTS
Industrial Automation and Robotics Technology	MECE574	Area Elective	3	0	0	3	5

Pre-requisite Course(s)
N/A

Course Language	English
Course Type	Elective Courses
Course Level	Ph.D.
Mode of Delivery	Face To Face
Learning and Teaching Strategies	Lecture.
Course Coordinator
Course Lecturer(s)	Assoc. Prof. Dr. Muhammad Umer KHAN
Course Assistants
Course Objectives	The main objective of this course is to familiarize students with the interdisciplinary field of robotics. The student must learn the Kinematics and Dynamics model of Serial manipulator, their correspondence with the real world. The course is designed with the objective of introducing students to the position and velocity-based control of robots. At the end of the course, the students should have gained aptitude in understanding, designing and implementation of the robot's control to perform certain task. Development, Simulation, and Analysis in RoboDK (https://robodk.com)
Course Learning Outcomes	The students who succeeded in this course; The students should be able to classify robots based upon their movement, and evaluate the performance based upon their specifications. In addition, basic elements of the robot will be explored and their movement in different coordinates and in view from different reference frames. The students must be able to transform the 3D position of the robot to its equivalent joint angles or contrarily transform the joint angles to the corresponding 3D position of the robot. In simple, the objective is to control both the position and orientation of the tool in 3D space. The students should be able to learn about differential motions of frames relative to a fixed frame, differential motions of robot joints relative to a fixed frame, Jacobians, and robot velocity relationships. The students should achieve the understanding of Lagrangian mechanics with the objective of utilizing robot motion. Öğrencilerin robot hareketini kullanabilmeleri için Lagrangian mekaniğinin anlaşılması gerekmektedir.
Course Content	Principles of industrial automation systems, system approach for automated machinery and plants; advanced topics in pneumatic and hydraulic components and systems, design of pneumatic and hydraulic systems; principles of industrial robots and their role in industrial automation, mobile robots, robot arms, AS/RS; design issues in industrial automati

Weekly Subjects and Releated Preparation Studies

Week	Subjects	Preparation
1	Fundamentals: What is a Robot? Classification, History	Reviewing the course content
2	Components, Degrees of Freedom Joints, Coordinates, Reference Frames, Characteristics, Workspace, Applications	Repeat the previous week.
3	Robot Kinematics: Coordinate Frames, Matrix Representation	Repeat the previous week.
4	Homogeneous Transformation Matrices, Denavit-Hartenberg	Repeat the previous week.
5	Representation of Forward Kinematic Equations of Robots, Inverse Kinematic Solution of Robots. Types of Planar and Spatial mechanism. Degeneracy and Dexterity. The Fundamental Problem with the Denavit-Hartenberg Representation.	Repeat the previous week.
6	Differential Motions and Velocities.	Repeat the previous week.
7	Differential Relationships. Jacobian. Differential Motions of a Frame. Interpretation of Differential Change. Differential Changes Between Frames. Differential Motions of a Robot and Its Hand Frame. Calculation of the Jacobian. How to Relate the Jacobian and the Differential Operator. Inverse Jacobian.	Repeat the previous week.
8	Midterm	Study Midterm
9	Dynamic Analysis and Forces	Repeat the previous week.
10	Lagrangian Mechanics, Dynamic Equations for Multiple-Degree-of-Freedom Robots. Static Force Analysis of Robots, Transformation of Forces and Moments Between Coordinate Frames	Repeat the previous week.
11	Trajectory Planning	Repeat the previous week.
12	Path vs. Trajectory. Joint Space vs. Cartesian-Space.	Repeat the previous week.
13	Basics of Trajectory Planning. Joint space trajectory planning, Cartesian space trajectories	Repeat the previous week.
14	Robot Kontrolü, Doğrusal Geri Bildirim Sistemleri, PD-Yerçekimi Kontrolü, Hesaplamalı Tork Kontrolü	Repeat the previous week.

Sources

Course Book	1. Peter Corke, "Robotics, Vision and Control", Springer, 2011 Saeed B. Niku, "Introduction to Robotics: Analysis, Systems, Applications", Pearson Education, 2003
	2. Robert J. Schilling, "Fundamentals of Robotics", Prentice Hall, 2005 J. J. Craig, Introduction to Robotics, Mechanics and Control, Pearson, Prentice Hall, 3rd Ed., 2005
	3. M.W. Spong, S. Hutchinson, M. Vidyasagar, Robot Modeling and Control, Wiley, 2006.

Evaluation System

Requirements	Number	Percentage of Grade
Attendance/Participation	-	-
Laboratory	-	-
Application	-	-
Field Work	-	-
Special Course Internship	-	-
Quizzes/Studio Critics	2	10
Homework Assignments	2	10
Presentation	-	-
Project	1	30
Report	-	-
Seminar	-	-
Midterms Exams/Midterms Jury	1	30
Final Exam/Final Jury	1	20
Toplam	7	100

Percentage of Semester Work
Percentage of Final Work	100
Total	100

Course Category

Core Courses	X
Major Area Courses
Supportive Courses
Media and Managment Skills Courses
Transferable Skill Courses

The Relation Between Course Learning Competencies and Program Qualifications

#	Program Qualifications / Competencies	Level of Contribution
#	Program Qualifications / Competencies	1	2	3	4	5
1	Obtain ability to carry out advanced research activities, both individual and as a member of a team
2	Obtain ability to evaluate research topics and comment with scientific reasoning
3	Obtain ability to initiate and create new methodologies, implement them on novel research areas and topics
4	Obtain ability to produce experimental and/or analytical data in systematic manner, discuss and evaluate data to lead scintific conclusions
5	Obtain ability to apply scientific philosophy on analysis, modelling and design of engineering systems
6	Obtain ability to synthesis available knowledge on his/her domain to initiate, to carry, complete and present novel research at international level
7	Contribute scientific and technological advancements on engineering domain of his/her interest area
8	Contribute industrial and scientific advancements to improve the society through research activities

ECTS/Workload Table

Activities	Number	Duration (Hours)	Total Workload
Course Hours (Including Exam Week: 16 x Total Hours)	14	3	42
Laboratory
Application
Special Course Internship
Field Work
Study Hours Out of Class	14	1	14
Presentation/Seminar Prepration
Project	1	16	16
Report
Homework Assignments	2	5	10
Quizzes/Studio Critics	2	5	10
Prepration of Midterm Exams/Midterm Jury	1	20	20
Prepration of Final Exams/Final Jury	1	20	20
Total Workload			132